Editing device and editing method

ABSTRACT

According to the present invention, there is provided an editing device for editing a plurality of channel data recorded on a record medium having a unit of writing data determined to be a predetermined data unit length, in which in performing an editing processing with respect to specific channel data having a length that is equal to or shorter than the predetermined data unit length designated by a user, the predetermined data unit length including the specific channel data is reproduced and stored to a memory, the editing operation is performed on the memory and the predetermined data unit length after the editing operation is read from the memory and is again recorded on the record medium whereby the editing processing such as copying, moving, exchanging, erasing and the like can be performed with respect to the short data of the predetermined data unit length or shorter.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to an editing device. For example, thepresent invention is applicable to the case where audio data recorded ina magneto-optic disk device is edited. The present invention is capableof editing audio data among a plurality of channels by reading audiodata at a pre edit portion from a record medium and recording the dataat a post edit portion after processing it.

Description of Related Art

Conventionally, in a magneto-optic disk device, continuous audio data isrecorded in the unit of cluster and recorded audio data is controlled bya UTOC (User-Table of Contents).

FIGS. 1A, 1B, 1C and 1D are outline diagrams showing the constitution ofa cluster. An magneto-optic disk device inputs to an audio compressioncircuit audio data of right and left channels that is successivelyinputted and respectively blocks the audio data at a predeterminedperiod (11.61 msec). Further, after compressing the audio data inrespect of a time axis in the unit of block, the audio data (R and L) ofthe right and left channels are multiplexed as shown by FIG. 1D.Hereinafter, audio data having the period of 11.61 msec of the twochannels that is compressed in respect of a time axis, is referred to assound group.

The magneto-optic disk device forms one sound frame by continuous elevensound groups as shown by FIG. 1C. As shown by FIG. 1B, one sound frameis allotted to two sectors. Further, as shown by FIG. 1A, three linksectors L and one sub sector S are added to 32 sectors allocated withthe audio data and one cluster is formed by 36 sectors. Incidentally,the link sector L is a sector for connecting clusters allocated withpredetermined data having no significance in place of audio data and subsector S is a sector allocated with sub data.

As shown by FIG. 2 in a style of a table, each sector is constituted bydata of 2352 bytes and a region thereof represented by longitudinaldirection addresses of "0" through "3", is allocated to a header. Inrespect of the header, the regions of longitudinal direction addressesof "0" through "2" of 12 bytes, are allocated to synchronization (sync)patterns and addresses of clusters are allocated to a first byte and asecond byte of the successive longitudinal direction address "3".Further, an address of a sector is allocated and a mode of amagneto-optic disk is recorded. Successive to the header, the main dataarea of 2336 bytes is formed and audio data that is compressed inrespect of a time axis is allocated to the region in the unit of a soundgroup.

According to the magneto-optic disk device of this kind, successivelyinputted audio data is successively allocated to a cluster in this way,the audio data is recorded successively in unrecorded regions and theaudio data is overwritten and recorded successively in erasable regions.In this case, when it becomes difficult to record a series of audio datato one continuous region, the remaining audio data is recorded in otherrecordable region or erasable region in the unit of cluster.

In respect of the audio data record of the unit of cluster, according tothe magneto-optic disk, record regions are formed on an inner peripheralside of the magneto-optic disk and the audio data is controlled bycontrol data recorded in the control region.

According to the magneto-optic disk, the UTOC data is allocated to thecontrol data. When the magneto-optic disk is loaded, the magneto-opticdisk device gains access to the UTOC data and rewrites the UTOC data asnecessary when the UTOC is requested to rewrite as in cutting off powersource, discharging the magneto-optic disk or the like.

In the UTOC data, a first through a fourth sector are set in the unit ofsector similar to the case of audio data and the second through thefourth sectors among them, are set to option. In the first sector (thatis, sector 0) as shown by FIG. 3, cluster addresses are allocated insuccession to the header and thereafter, data of 00h, fabrication makerof recording device, model code of recording (Maker code, Model code),start number and finish number of recorded program First TNO, Last TNOand the like are allocated successively.

The first sector is successively allocated with identification data ofdisk (DISC.ID), a pointer showing a front slot of a position of adefective area in a program region (Pointer for Defective Area: P-DFA),with respect to slot, mentioned later, a pointer showing a front slot ofvacant slot (Pointer for Empty Slot: P-EMPTY), and a pointer showing afront slot of a recordable region in a program region (Pointer forFreely Area: P-FRA).

Further successively, pointers (P-TNO1, . . . , P-TNO255) are allocatedand in regions of a longitudinal address "76" or thereafter, slots inthe unit of 8 bytes are allocated. Here, each slot is recorded with astart address (Start address), an end address (End address), a trackmode (Track mode) and a link pointer (Link-P).

Here, pointers (P-TNO1, . . . , P-TNO255) correspond to a musicalcomposition recorded on the magneto-optic disk and designate addressesof corresponding slots. Further, start address (Start address) and endaddress (End address) designate a record start position and recordfinish position of continuous audio data by cluster address, sectoraddress and sound group. Hereinafter, a record unit designated by startaddress (Start address) and end address (End address) is referred to aspart. When continuous audio signals are divided and recorded to otherregions of the magneto-optic disk, link pointer (Link-P) designates aslot corresponding to continuous audio signal (comprising continuousparts). Incidentally, mode data (Track mode) records a mode of eachpart. The mode data records identification data of copyprohibition/allowance, audio data/computer data and the like.

Thereby, as shown by, for example, FIG. 4, when audio data is recordedfirstly on a magneto-optic disk where no audio data is recorded, audiodata is recorded in the magneto-optic disk by forming parts P1, P2, P3and P4 corresponding to the respective musical plays such that the firstmusical composition, the second musical composition, are successivelyand continuously played by designating pointers (P-FRA) representingfront positions of recordable regions. In correspondence thereto, startaddresses and end addresses of the respective parts P1, P2, P3 and P4are successively recorded in the respective slots and slots ofrespective plays are designated by the respective pointers P-TNO1,P-TNO2, P-TNO3 and P-TNO4.

Incidentally, when the second musical composition is intended to erasein the continuously recorded audio data, the magneto-optic disk deviceconnects a slot in correspondence with the erase program to a final slotlinked by P-FRA. That is, the pointer (P-FRA) designates a correspondingslot similar to the pointers (P-FRA, P-TNO1, . . . , P-TNO255). Thereby,according to the magneto-optic disk device, for example, the secondmusical composition and the fourth musical composition are intended toerase, in respect of designating slots in correspondence with parts P2and P4 by pointers (P-TNO1, P-TNO2, . . . ) until then, slots in each ofwhich start address, end address and link pointer are recorded in therecordable region designated by P-FRA, are successively searched basedon the link pointer and are successively connected to the final slot.The connecting operation is realized by having the link pointer of thefinal slot of the recordable region designate the slots controlling thesecond musical composition and the fourth musical composition.

According to the connecting operation, the link pointer of the finalslot searched by LINK-P, is recorded with Null data, the Null data isrewritten to designate the slot in correspondence with the erased secondmusical composition, the link pointer of the slot corresponding to thesecond musical composition is rewritten to designate the slot incorrespondence with the fourth musical composition that is intended toerase and the link pointer of the slot in correspondence with the fourthmusical composition is recorded with the Null data.

The recording of the Null data in the link pointer signifies that nocontinuous link slot is present.

In this way, according to the magneto-optic disk device, the audio datais recorded in the unit of cluster and the recorded audio data iscontrolled by UTOC by which even if processings of recording and erasingare repeated, UTOC is rewritten in correspondence with the processings,the continuous audio data is discretely recorded and the discretelyrecorded audio data is reproduced. By that amount, the program region ofthe magneto-optic disk can effectively be used.

By contrast, in editing, the magneto-optic disk device changes the playorder of the audio data recorded in the magneto-optic disk by rewritingpointers (P-TNO1, P-TNO2, . . . ) or by rewriting the slots respectivelydesignated by the pointers (P-TNO1, P-TNO2, . . . ).

As shown by FIGS. 5A and 5B, for example, when P1 of a first musicalcomposition of FIG. 5A is divided in two by which a processing ofdividing the first musical composition into two musical compositions iscarried out, the end address is changed from S2 to S3 without changingthe start address of the slot designated by P-TNO1. The link pointer isrecorded with the Null data since there is no successive slot.

Further, the start address of the slot designated by P-TNO2 is changedfrom S2 to S3 and also, the end address is changed from S4 to S3. Thelink pointer is recorded with the Null data since there is no successiveslot.

In FIG. 5A, only the two musical compositions are recorded andtherefore, P-TNO3 does not designate a specific slot. However, accordingto FIG. 5B showing a state after the division processing, P-TNO3 isedited to designate a new slot whereby S2 is recorded to the startaddress of the slot designated by P-TNO3 and S4 is recorded to the endaddress thereof. The link pointer is recorded with the Null data sincethere is no successive slot.

The division processing of a musical composition can be carried out byperforming the edition on U-TOC as described above.

Incidentally, the start and the end address of the slot designated byP-TNO2 are equal to the start address and the end address of the thirdmusical composition after edition and therefore, the designation ofdestination by P-TNO3 may be edited to designate the slot designated byP-TNO2, P-TNO2 may be edited to designate a new slot, S3 may be recordedas the start address of a slot newly designated by P-TNO2 and S2 may berecorded as the end address thereof.

Incidentally, in this case, the start address of the slot designated byP-TNO1 is not naturally changed and the end address is naturally changedfrom S2 to S3.

In this way, according to the magneto-optic disk device, the audio datacan easily be edited in the unit of sound group by the simple processing of rewriting UTOC.

The editing processing which can be executed by controlling by UTOC inthis way, is a processing for rearranging audio data of two channelscomprising right and left channels simultaneously in the unit of soundgroup. Thereby, when the editing processing is performed betweenchannels in the conventional magneto-optic disk device, it is necessaryto edit reproduced audio data by decompressing it in respect of a timeaxis and thereafter to rerecord it.

It seems that when the editing processing between channels can simply beexecuted as in the editing processing that is executed under control ofUTOC, the easiness of use of this kind of the magneto-optic disk devicecan further be promoted. Also, it seems to be convenient when the audiodata can be edited by multi channels by increasing a number of channelsthat can be edited.

The present invention has been carried out in consideration of theabove-described points and it is an object thereof to provide an editingdevice capable of simply editing audio signals among a plurality ofchannels.

SUMMARY OF THE INVENTION

In order to resolve such a problem, according to the present invention,there is provided an editing device including storing means for forminga plurality of channels by successively allocating blocks of audio datacirculatingly and storing audio data of a pre edit portion reproduced byreproducing means, audio signal modifying means for modifying the audiodata at the pre edit portion stored to the storing imeans and recordingmeans for recording the audio data at the pre edit portion stored to thestoring means to a post edit portion.

When the reproduced audio data at the pre edit portion is stored to thestoring means and the audio data is modified by the audio signalmodifying means, the audio data can be edited among the plurality ofchannels by the fabrication. Accordingly, the audio data can simply beedited among the plurality of channels recorded on a record medium byrecording the audio data at the pre edit portion stored to the storingmeans.

In view of the above points, according to the present invention, thereis provided an editing device in which on a record medium having a unitof writing data determined to be a predetermined length, a plurality ofchannel data having a unit channel data length shorter than the unitlength of writing data are recorded by being subjected to time divisionmultiplexing and an editing processing is performed with respect topredetermined channels of the plurality of channels, the editing deviceincluding,

an operation key for designating an editing range of a first specificchannel data that is a pre edit portion designated by a user and anediting position of a second specific channel data that is a post editportion designated by the user,

a reproducer for reproducing the plurality of channel idata in respectof the editing range from the record medium based on the editing rangeof the pre edit portion designated by the operation key and reproducingthe plurality of channel data in respect of the post edit portion fromthe record medium based on the designated editing position at the postedit portion designated by the operating means,

a first memory for storing the plurality of channel data at the pre editportion reproduced by the reproducer at each of the unit of writingdata,

a second memory for storing the plurality of channel data at the postedit portion reproduced by the reproducer at each of the unit of writingdata,

an overwriter for reading the first specific channel data constitutingthe pre edit portion designated by the user from the first memory andoverwriting the read first specific channel data from a positioncorresponding to the second specific channel data at the post editportion stored by the second memory, and

a recorder for recording again the plurality of channel data stored tothe second memory to a portion on the record medium situated before theediting processing after the specific channel data has been overwrittento the second memory.

Further, according to the present invention, there is provided anediting device in which on a record medium having a unit of writing datadetermined to be a predetermined length, a plurality of channel datahaving a unit channel data length shorter than the unit length ofwriting data are recorded by being subjected to time divisionmultiplexing and an editing processing is performed with respect topredetermined channels in the plurality of channels, the editing deviceincluding,

an operation key for designating an editing range of a specific channeldata designated by a user,

a reproducer for reproducing the plurality of channel data in respect ofthe editing range from the record medium based on the editing rangedesignated by the operation key,

a memory for storing the plurality of channel data which have beenreproduced by the reproducer at each of the unit of writing data,

an eraser for erasing the specific channel data having the editing rangedesignated by a user from the memory, and

a recorder for recording again the plurality of channel data stored tothe memory to a portion on the record medium situated before the editingprocessing after the specific channel data has been erased on thememory.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic view for explaining a cluster that is a unit ofwriting data recorded on the record medium that is applied to thepresent invention;

FIG. 1B is a schematic view for explaining a sector that is a datastructure recorded on the record medium applied to the presentinvention;

FIG. 1C is a schematic view for explaining a sound group that is a datastructured recorded on the record medium applied to the presentinvention;

FIG. 1D is a schematic view for explaining two channel data that is adata structure recorded on the record medium applied to the presentinvention;

FIG. 2 is a structural view of a sector applied to the presentinvention;

FIG. 3 is a schematic view showing U-TOC data that is control datarecorded on the record medium applied to the present invention;

FIG. 4 is a schematic view of a program recorded on the record mediumapplied to the present invention;

FIG. 5A is a schematic view of a program of two musical compositionsrecorded on the record medium applied to the present invention;

FIG. 5B is a schematic view after performing a division processing onthe first one of the two musical compositions in the program;

FIG. 6 is an outlook view of a recording device applied to the presentinvention;

FIG. 7 is an outlook view of an UNDO/REDO key installed on the recordingdevice;

FIG. 8 is a block diagram for explaining time division multiplexrecording and multiplex reproducing in a 4-channel recording andreproducing device applied to the present invention;

FIG. 9A is a schematic view showing a first channel in four channelsinputted to a recording device according to the present invention;

FIG. 9B is a schematic view showing a second channel in the fourchannels inputted to the recording device according to the presentinvention;

FIG. 9C is a schematic view showing a third channel in the four channelsinputted to the recording device according to the present invention;

FIG. 9D is a schematic view showing a fourth channel in the fourchannels inputted to the recording device according to the presentinvention;

FIG. 9E is a schematic view performing time division multiplexing oninput signal of the four channels;

FIG. 9F is a schematic view in which the time division multiplex signalis made to correspond to the sound group explained in FIG. 1C;

FIG. 9G is a schematic view for explaining the sector that is the datastructure recorded on the record medium applied to the presentinvention;

FIG. 9H is a schematic view for explaining the cluster which is the unitof writing data recorded on the record medium applied to the presentinvention;

FIG. 10A is a schematic view showing a first channel in two channelsinputted to a recording device according to the present invention;

FIG. 10B is a schematic view showing a second channel in the twochannels inputted to the recording device according to the presentinvention;

FIG. 10C is a schematic view performing time division multiplexing oninput signal of the two channels;

FIG. 10D is a schematic view in which the time division multiplex signalis made to correspond to the sound group explained in FIG. 1C;

FIG. 10E is a schematic view for explaining the sector that is the datastructure recorded on the record medium applied to the presentinvention;

FIG. 10F is a schematic view for explaining the cluster that is the unitof writing data on the record medium applied to the present invention;

FIG. 11A is a schematic view performing time division multiplexing oninput signals of one channel;

FIG. 11B is a schematic view in which the time division multiplex signalis made to correspond to the sound group explained in FIG. 1C;

FIG. 11C is a schematic view for explaining the sector that is the datastructure recorded on the record medium applied to the presentinvention;

FIG. 11D is a schematic view for explaining the cluster that is the unitof writing data recorded on the record medium applied to the presentinvention;

FIG. 12A is a schematic view of a program of two musical compositionsrecorded on the record medium applied to the present invention;

FIG. 12B is a schematic view after performing a copying processing onthe first one of the two musical compositions in the program;

FIG. 13A is a schematic view of a program of three musical compositionsrecorded on the record medium applied to the present invention;

FIG. 13B is a schematic view after performing a moving processing on theprogram of the three musical compositions;

FIG. 14A is a schematic view of a program of three musical compositionsrecorded on the record medium applied to the present invention;

FIG. 14B is a schematic view after performing an exchanging processingfor exchanging a first one and a third one of the three musicalcompositions in the program;

FIG. 15A is a schematic view of a program of three musical compositionsrecorded on the record medium applied to the present invention;

FIG. 15B is a schematic view after performing erasing processing withrespect to a first one of the three musical compositions in the program;

FIG. 16A is a schematic view of a program of three musical compositionsrecorded on the record medium applied to the present invention;

FIG. 16B is a schematic view after performing a combining processing forcombining a first one and a second one of the three musical compositionsin the program;

FIG. 17A is a schematic view of a program of three musical compositionsrecorded on the record medium applied to the present invention;

FIG. 17B is a schematic view after performing a dividing processing withrespect to a first one of the three musical compositions in the program;

FIG. 18A is a schematic view showing three parts recorded on the recordmedium applied to the present invention;

FIG. 18B is a schematic view after performing an inserting processingfor inserting a part P2 between two parts P11 and P12 in the threeparts;

FIG. 19A is a schematic view showing four parts recorded on the recordmedium applied to the present invention;

FIG. 19B is a schematic view after performing a moving processing formoving two parts P2 and P3 in the four parts ;

FIG. 20A is a schematic view showing four parts recorded on the recordmedium applied to the present invention;

FIG. 20B is a schematic view after performing an exchanging processingfor exchanging two parts P1 and P3 in the four parts;

FIG. 21A is a schematic view showing three parts recorded on the recordmedium applied to the present invention;

FIG. 21B is a schematic view after performing an erasing processing forerasing a part P2 that is the central one of the three parts;

FIG. 22 is a flowchart of an editing processing for moving or copying aportion of one channel data in multi channel data according to thepresent invention to other channel data;

FIG. 23A is a schematic view for explaining a cluster that is a unit ofwriting data recorded on the record medium applied to the presentinvention;

FIG. 23B is a schematic view for explaining a sector that is a datastructure recorded on the record medium applied to the presentinvention;

FIG. 23C is a schematic view for explaining a sound group that is a datastructure recorded on the record medium applied to the presentinvention;

FIG. 23D is a schematic view for explaining 4 channel data that is adata structure recorded on the record medium applied to the presentinvention;

FIG. 23E is a schematic view schematically rearranging the 4 channeldata time-sequentially and continuously;

FIG. 24A is a schematic view for designating a pre edit portion and apost edit portion in the 4 channel data arranged time-sequentially andcontinuously;

FIG. 24B is a schematic view of an inner portion of a memory when dataof the pre edit portion and data of the post edit portion are stored inthe memory;

FIG. 24C is a schematic view for copying 1 channel data at the pre editportion shown by the schematic view of the inner portion of the memoryto 3 channel data at the post edit portion;

FIG. 24D is a schematic view for explaining the copying operation of 1channel data at the pre edit portion to 3 channel data at the post editportion in 4 channel data arranged time-sequentially and continuously;

FIG. 25A is a schematic view for designating a pre edit portion and apost edit portion in 4 channel data arranged time-sequentially andcontinuously;

FIG. 25B is a schematic view of an inner portion of a memory when dataat the pre edit portion and data at the post edit portion are stored inthe memory;

FIG. 25C is a schematic view showing a so-called moving processing where1 channel data at the pre edit portion shown by the schematic view ofthe inner portion of the memory is copied to 3 channel data at the postedit portion and the 1 channel data at the pre edit portion is erasedafter the copying operation;

FIG. 25D is a schematic view for explaining movement of 1 channel dataat the pre edit portion to 3 channel data at the post edit portion in 4channel data arranged time-sequentially and continuously;

FIG. 26 is a flowchart showing an exchanging processing for exchanging aportion of one channel data of multi channel data according to thepresent invention with a portion of other channel data;

FIG. 27A is a schematic view for designating a first channel data and asecond channel data in 4 channel data arranged time-sequentially andcontinuously;

FIG. 27B is a schematic view of an inner portion of memory when thefirst channel data and the second channel data are stored in a memory;

FIG. 27C is a schematic view showing an exchanging processing in whichthe first channel data shown by the schematic view of the inner portionof the memory is exchanged with the second channel data;

FIG. 27D is a schematic view for explaining movement where the firstchannel data and the second channel data are exchanged with each otherin 4 channel data arranged time-sequentially and continuously;

FIG. 28 is a flowchart showing an erasing processing for erasing oneportion of one channel data in multi channel data according to thepresent invention;

FIG. 29A is a schematic view for designating the channel data intendedto erase in 4 channel data arranged time-sequentially and continuously;

FIG. 29B is a schematic view of an inner portion of a memory when theerased and designated channel data is stored in a memory;

FIG. 29C is a schematic view showing an erasing processing in whichsoundless data is recorded at a portion of channel data intended toerase in the memory;

FIG. 29D is a schematic view of writing an erased portion by the unit ofcluster on the memory in 4 channel data arranged time-sequentially andcontinuously;

FIG. 30 is a flowchart for escaping data for restoring at an occasion ofUNDO in performing an UNDO/REDO processing;

FIG. 31A is a schematic view of escaping data at a post edit portion toan escaping region;

FIG. 31B is a schematic view of performing an editing processing from apre edit portion to the post edit portion after the escaping processing;

FIG. 31C is a schematic view of returning data which has been present atthe pre edit portion before the editing operation and which has beenmoved to the post edit portion and returning data escaped at theescaping region to the original post edit portion when an UNDO operationis designated; and

FIG. 32 is a flowchart showing a processing content when an UNDOprocessing is designated.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A detailed explanation will be given of embodiments of the presentinvention pertinently in reference to the drawings as follows.

(1) Total constitution

FIG. 6 is a perspecti ve view sho wing a magneto-optic disk deviceaccording to an embodiment of the present invention. According to amagneto-optic disk device 1, as shown by an arrow mark A, a diskcassette 3 is inserted from a disk insertion port 2 arranged at a sideface, audio signals are recorded on a magneto-optic disk held by thedisk cassette 3 and audio signals re corded on the magneto-optic diskare edited and reproduced.

Here, according to t he magneto-optic disk applied to the magneto-opticdisk device 1, a pre-groove for guiding a laser beam is formed tomeander on an information record face, the disk can be driven to rotateat a predetermined rotational speed and the address of a laser beamirradiating position can be detected with the frequency of meandering asa reference. Further, the information record face is concentricallydivided and the outer peripheral side is allocated to a program regionfor recording audio signals and the inner peripheral side is allocatedto a control region. According to the magneto-optic disk, control dataconstituted by P-TOC (Pre-mastered Table of Content) and U-TOC forcontrolling the program region is recorded in the control region. Themagneto-optic disk is formed to be able to make an access to PTOC regionwith data of UTOC as a reference and UTOC is formed by a formatdescribed above in reference to FIG. 3.

Further, the top face of the magneto-optic disk device 1 is set as anoperation panel, at least 1 channel of audio signals are inputted via aconnector 4 arranged at the upper portion of the operation panel and arerecorded in the magneto-optic disk and the recorded audio signal isoutputted. In the magneto-optic disk device 1, master operators 5 arearranged for the respective channels on the left side of the operationpanel and sound volume or the like can be adjusted by operating theoperators 5.

According to the magneto-optic disk device 1, various operators 7 arearranged contiguous to the operators 5, a jog dial 8 is arranged on thelower side of the operators 7 and a display panel 9 is arranged at theupper portion of the operators 7 by which, for example, an in point, anout point and the like can be set by operating the jog dial 8 whileconfirming the display of the display panel 9. Operators 10 forreproducing or the like are arranged contiguous to the jog dial 8 andaudio signals can be recorded and reproduced by operating the operators10.

According to the magneto-optic disk device 1, one of the operators 7used in setting an in point or the like in this way, is set to anoperator of Undo and Redo and processings of Undo and Redo are executedby repeatedly pushing the operator.

FIG. 7 is a plane view showing the operator 7A of Undo and Redo where adisplay of "UNDO" indicating the function of the operator is formed onthe upper face of the operator 7A that is pushed by finger and a window7B is formed at the corner portion on the left upper side. The window 7Bis illuminated in green by light emitting diode arranged at the insidethereof and the magneto-optic disk device 1 illuminates the window 7B asnecessary to be able to transfer various information to a user.

FIG. 8 is a block diagram showing the constitution of a digital signalprocessing unit of the magneto-optic disk device 1. According to themagneto-optic disk device 1, an analog to digital conversion circuit(A/D) 12 subjects audio signals SA1 through SA4 of a maximum of 4channels inputted from the connector 4 to an analog to digitalconversion processing by a predetermined sampling frequency by whichdigital audio signals are outputted.

A data compression circuit 13 blocks the digital audio signals outputtedfrom the analog to digital conversion circuit 12 by subjecting them totime division at the frequency of 11.61 msec and compresses the digitalaudio signals by data compression by the unit of each block.

A time correction circuit 14 converts the digital audio signalsoutputted from the data compression circuit 13 into one digital audiosignal DAl and outputs it to a data bus BUS by being controlled by asystem control circuit 15 in respect of the operation.

An explanation will be given of the procedure of blocking the audiosignals inputted via 4 channels by the unit of one cluster as follows.As shown by FIGS. 9A through 9H, in recording the audio signals SA1through SA4 of 4 channels inputted from the connector 4, the timecorrection circuit 14 subjects the respective blocks at the frequency of11.61 msec to time division multiplexing successively and circulatinglywhereby the digital audio signal DA1 as shown by FIG. 9E is formed.

As shown by FIG. 9F, the magneto-optic disk device 1 forms one soundgroup by continuous two blocks of the digital audio signal DA1 andallocates continuous 11 sound groups to 2 sectors. Further, as shown byFIG. 9H, sets of three link sectors L and one sub sector S are addedbefore and after continuous 32 sectors whereby 1 cluster is formed.Incidentally, in this case a sound frame is formed by 22 sound groups.

By contrast, as shown by FIGS. 10A through 10F, in recording audiosignals SA1 and SA2 of 2 channels, the time correction circuit 14similarly subjects the respective blocks at the period of 11.61 msec totime division multiplexing successively and circulatingly by which thedigital audio signal DA1 is formed.

An explanation will be given of the procedure of blocking the audiosignals inputted via 2 channels by the unit of one cluster.

As shown by FIG. 10D, similar to the case of 4 channels, themagneto-optic disk device 1 forms 1 sound group by continuous 2 blocks,and as shown by FIG. 10E, allocates 11 sound groups to 2 sectors. Asshown by FIG. 10F, sets of link sectors L and one sub sector S are addedto before and after continuous 32 sectors by which 1 cluster is formed.Incidentally, in this case a sound frame is formed by 11 sound groups asin the case of the stereo described in reference to FIGS. 1A through 1D.

As shown by FIGS. 11A through 11D, in recording an audio signal SA1 of 1channel, the time correction circuit 14 forms the digital audio signalDAI by successively and timewisely arranging the respective blocks atthe period of 11.61 msec.

Also in this case, similar to the case of 4 channels, the magneto-opticdisk device 1 forms 1 sound group by continuous 2 blocks and allocates11 sound groups to 2 sectors as shown by FIG. 11C. Further, sets of linksectors L and one sub sector S are added to before and after continuous32 sectors by which 1 cluster is formed. Also in this case, similar tothe case of the stereo described above in reference to FIGS. 1A through1D, a sound frame is formed by 11 sound groups. Incidentally, in respectof the number of channels, mode data (TRACK MODE) allocated to therespective slots of UTOC are set by the system control circuit 15 andare recorded on the magneto-optic disk.

By contrast, in the reproducing operation, the time correction circuit14 demodulates the digital audio signal DAl successively inputted fromthe data bus BUS into the original digital audio signals that is anoperation reverse to that in recording in accordance with the format ofaudio signal recorded on the magneto-optic disk, and outputs them underthe control of the system control circuit 15.

A data decompression circuit 18 decompresses the digital audio signalsoutputted from and compressed by the time correction circuit 14 in thereproducing operation, which is an operation reverse to that of the datacompression circuit 13. A digital to analog conversion circuit (D/A) 19subjects the digital audio signal outputted from the data decompressioncircuit 18 to a digital to analog conversion processing and outputs theaudio signals SA1 through SA4.

A memory 20 is constituted by a memory circuit having a large capacitythat is operated under the control of the memory control circuit 21 andinputs and holds the digital audio signal DA1 outputted from the timecorrection circuit 14 via the data bus BUS in the recording operation.Further, the memory 20 stores the link sectors L, the sub sectors S, theheaders of the respective sectors, cluster addresses and the like by amemory control circuit 21 by which record data having theabove-described cluster structure is formed by adding these data to thedigital audio signal DA1 as described above in reference to FIGS. 9Athrough 9H, FIGS. 10A through 10F and FIGS. 11A through 11D. The memory20 outputs the record data to the data bus BUS by the unit of cluster attimings in synchronism with the rotation of the magneto-optic disk.

In the reproducing operation, the memory 20 inputs decoded dataoutputted from a signal processing circuit 23 via the data bus BUS bythe unit of cluster and temporarily stores it. Further, the digitalaudio signal DA1 is outputted by removing extra data such as headers andthe like from the decoded data.

In the editing operation, the memory 20 inputs the decoded dataoutputted from the signal processing circuit 23 by the unit of clusterand temporarily stores it under the control of the memory controlcircuit 21. Further, the temporarily stored decoded data is modified byswitching the addresses by the unit of blocks of the digital audiosignal DAl and updating it by data outputted from the memory controlcircuit 21 in accordance with the content of the editing processing.Further, the memory 20 outputs the temporarily stored decoded data tothe signal processing circuit 23 via the data bus BUS.

A disk unit 22 drives to rotate the magneto-optic disk contained in thedisk cassette 3 and irradiates a laser beam by an optical pickup underthe state. Further, the disk unit 22 receives return light of the laserbeam by the optical pickup and drives to rotate the magneto-optic diskat a predetermined rotational speed in accordance with the receivedlight result with the pre-groove of the magneto-optic disk as areference and detects the address of the laser beam irradiatingposition.

The disk unit 22 performs a tracking control and a focusing control withthe received result of return light as a reference and makes the opticalpickup seek the recording and reproducing position designated by thesystem control circuit 15 with the address of the laser beam irradiatingposition as a reference. By the seeking operation, the disk unit 22makes an access to PTOC and UTOC in loading and discharging themagneto-optic disk and makes an access to the program region inrecording, reproducing and editing.

The disk unit 22 forms a reproducing signal the signal level of which ischanged in accordance with a change in the deflected face for deflectingthe return light and forms a binarized signal from the reproducingsignal. Further, the disk unit 22 forms reproduce clocks from thebinarized signals and forms reproduce data by successively latching thebinarized signals by the reproduce clocks.

In the recording operation, the disk unit 22 intermittently makes risethe amount of light of the laser beam at the recording and reproducingposition designated by the system control circuit 15. Under the state,the disk unit 22 drives a modulating coil by modulation data outputtedfrom the signal processing circuit 23 and applies a modulated magneticfield formed by the modulating coil at the laser beam irradiationposition. In this way, the disk unit 22 records the modulated data byapplying the method of thermomagnetic recording.

In the editing operation, the disk unit 22 repeats the above-describedprocessing in the reproducing operation and the processing in therecording operation as necessary, by which the reproduced data isoutputted to the signal processing circuit 23 and the modulation dataoutputted from the signal processing circuit 23 is recorded to themagneto-optic disk.

After decoding the reproduced data outputted from the disk unit 22, thesignal processing circuit 23 performs an error correction processing bywhich data of PTOC and UTOC and demodulation data are formed from thereproduced data and outputted to the data bus BUS. By contrast, in therecording operation, the signal processing circuit 23 adds an errorcorrection code to the recorded data outputted to the data bus BUSthereafter, performs an encoding processing by which the modulation datais formed and outputted to the disk unit 22. Further, in the editingoperation, the above-described processing in the reproducing operationand the processing in the recording operation are repeated as necessary,by which the decoded data is outputted to the memory 20 and themodulation data is formed from the recorded data outputted from thememory 20 and outputted.

In loading the magneto-optic disk, a TOC memory 24 inputs and holds thedata of PTOC and UTOC outputted from the signal processing circuit 23and outputs the held data to the system control circuit 15 as necessary.Further, in the recording operation and editing operation, the held datais outputted to the system control circuit 15 at request from the systemcontrol circuit 15 and the held data is updated. Further, the TOC memory24 outputs the held data of UTOC to the signal processing circuit 23 indischarging the magneto-optic disk and updates UTOC of the magneto-opticdisk by the data of UTOC.

The system control circuit 15 is constituted by a microcomputer forcontrolling the operation of a total of the magneto-optic disk device 1,switches the total in accordance with the operation of the respectiveoperators 5, 7, 8 and 10 and switches the display of the display panel9.

When the disk cassette is loaded, the system control circuit 15 loadsthe data of PTOC to the TOC memory 24 by driving the disk unit 22.Further, the disk unit 22 is driven in accordance with the data of PTOCloaded to the TOC memory 24 and the successive data of UTOC is loaded tothe TOC memory 24.

When the record mode is set by operating the operators under the state,slots are successively searched by pointer (P-FRA) of UTOC, a startaddress and an end address of a recordable region are successivelydetected and the disk unit 22 is driven by the start address and the endaddress. By setting the operation of the time correction circuit 14 andthe like to the operation mode in the recording operation, the systemcontrol circuit 15 makes an access successively to the recordable regionof the magneto-optic disk and records the successively inputted audiosignal to the magneto-optic disk. In this case, the system controlcircuit 15 displays a recording time period, a remaining recordable timeperiod and the like by driving the display panel 9.

Furthermore, the system control circuit 15 updates the data of UTOCstored in the TOC memory 24 when the recording operation is finishedwith respect to one musical composition of the audio signal. That is,with respect to parts recording the one musical composition of the audiosignal, pointers (P-TNO1, . . . , P-TNO255) and corresponding slots areupdated by which the one musical composition of the audio signal isregistered to UTOC. Further, the pointer (P-FRA) designating therecordable range is updated by which the parts recording the audiosignal is deleted from the recordable range.

By contrast, when the reproducing mode is set, the slots designated bypointers (P-TNO1, . . . , P-TNO255) are successively searched, the startaddresses and the end addresses of the successively corresponding slotsare detected and the disk unit 22 is driven by the detected addresses.Next, the system control circuit 15 sets the operation of the timecorrection circuit 14 and the like to the operation mode in thereproducing operation by which the audio signals recorded to themagneto-optic disk are successively reproduced and outputted to anoutside device.

At this moment, the system control circuit 15 displays the name of thereproduced musical composition, the number of the musical composition,the reproducing time period and the like on the display panel 9 inaccordance with the content recorded to the predetermined UTOC by dataof UTOC stored in the TOC memory 24 and the musical composition and thechannel designated by a user are selectively reproduced.

The system control circuit 15 receives setting of editing points such asin points, out points and the like by the operation of the jog dial 8and the operation of the operators 7 by a user and when the reproductionin accordance with the editing point is designated, the audio signalsdesignated by the editing point is selectively reproduced.

(1-1) Editing processing

When a user selects the operation mode of editing, the system controlcircuit 15 executes the editing processing by the unit of the musicalcomposition, the editing operation with respect to a portion of themusical composition and the editing operation among channels inaccordance with the operation of the user.

The editing processing by the unit of the musical composition is aso-called UTOC editing processing executed by the unit of the pointers(P-TNO1, . . . , P-TNO255) of UTOC and is executed when the userdesignates the musical composition and selects the mode of editing. Inthe editing operation by the unit of the musical composition, the systemcontrol circuit 15 executes processings of copying, moving, exchanging,erasing, combining or dividing in accordance with the selectingoperation of the user.

As shown by FIGS. 12A and 12B, the copying processing is a processingfor copying the musical composition selected by the user to therecordable region of the magneto-optic disk and when the musicalcomposition is designated, the system control circuit 15 makes an accessto the TOC memory 24 and detects the start address S1 and the endaddress E1 of a copied portion by the corresponding pointer (P-TNO1).Further, the system control circuit 15 drives the disk unit 22 with thestart address S1 and the end address E1 as references, reproduces themagneto-optic disk by the unit of cluster in a range storable to thememory 20 and stores the demodulation data obtained from the signalprocessing circuit 23 to the memory 20.

As shown by FIG. 12B, the system control circuit 15 detects therecordable region based on the pointer (P-FRA) and records thedecompression data held by the memory 20 to a copying portion with theaddress S3 at the copying portion as a reference. The system controlcircuit 15 repeats the reproducing and recording processings withrespect to the musical composition designated by the user and copies afirst musical composition as a third musical composition in this case.The repeating operation of the reproducing and recording processings isnot necessary when the capacity of the memory 20 is sufficiently large.

Successively, the system control circuit 15 makes an access to the TOCmemory 24 and registers the start address S3 and the end address E3 ofthe third musical composition to the slots designated by the pointer(P-TNO3).

Hereinafter, the moving processing of the musical composition is shownin FIGS. 13A and 13B. The moving processing is a processing for movingthe position of the designated musical composition and when the musicalcomposition is designated, the system control circuit 15 makes an accessto the TOC memory 24 and rewrites the addresses of the parts designatedby the pointers (P-TNO X: (X=1-255) ) of the designated musicalcompositions. That is, when a first, a second and a third slots aredesignated successively by the first, the second and the third pointersP-TNO1, P-TNO2 and P-TNO3, the addresses are rewritten to designate thesecond, the third and the first slots by the first, the second and thethird pointers P-TNO1, P-TNO2 and P-TNO3 and the order of the musicalcompositions is switched. Here, caution is required to the fact that thestart addresses, the end addresses and the link data constitutingcontents of the slots are not rewritten but the slot numbers recorded inP-TNO are rewritten.

Hereinafter, as shown by FIGS. 14A and 14B, the exchanging processing isa processing for exchanging the designated musical compositions and thesystem control circuit 15 exchanges the order of the musicalcompositions by rewriting addresses of parts designated by the pointers(P-TNO X:(X=1-255)) with respect to the designated musical compositionssimilar to the case of the moving processing.

In the case of FIGS. 14A and 14B, the slot number designated by P-TNO1and the slot number designated by P-TNO3 are exchanged and rewritten.

As shown by FIGS. 15A and 15B, the erasing processing is a processingfor erasing the designated musical composition and the system controlcircuit 15 executes a processing reverse to the updating processing ofthe TOC memory 24 that is executed in the copying operation with respectto the designated musical composition.

That is, the system control circuit 15 makes an access to the TOC memory24 and releases the designation of the part by the pointer (P-TNO1, . .. , P-TNO255) designating the part (comprising the start address S1 andthe end address E1) of the fist musical composition and adds the slotcomprising the start address S1 and the end address E1 to the slotdesignated by the pointer (P-FRA) of the recordable region.

As shown by FIGS. 16A and 16B, the combining processing is a processingfor combining the designated musical compositions and when the firstmusical composition and the second musical composition are designated,the system control circuit 15 makes an access to the TOC memory 24 andsets the address designating the slot of the second musical compositionto the link pointer LINK-P of the slot designated by the pointer P-TNO1of the first musical composition. The pointer P-TNO2 of the secondmusical composition is updated such that the slot designated by P-TNO3is designated.

Further, the slot is prevented from being designated by recording theNull data to P-TNO3.

As shown by FIGS. 17A and 17B, the dividing processing is a processingfor dividing one musical composition into a plurality of musicalcompositions and when the first musical composition is designated, thesystem control circuit 15 makes an access to the TOC memory 24 andupdates the address of the inputted editing point as an end address E11by operating the jog dial 8 with respect to the slot of the firstmusical composition.

Further, the slot number recorded to the pointer P-TNO3 corresponding tothe third musical composition is copied to P-TNO4 and the slot numberrecorded to the pointer P-TNO2 corresponding to the second musicalcomposition is copied to P-TNO3. Further, an empty slot designated byP-EMPTY is designated to the pointer P-TNO2 corresponding to the secondmusical composition by which S11 successive to E11 formed by thedividing processing, is recorded as the start address of a new slotdesignated by the pointer P-TNO2 and E1 is recorded to the end address.Although an explanation has been given of the above-describedprocessings with respect to various editing processings by the unit ofone musical composition, the various editing processings can beperformed with respect to a finer portion in the musical composition.

The above-described editing processing with respect to a portion of themusical composition is a so-called UTOC editing processing for editingaudio signals by the unit of sound group comprising the unit ofrecording in the magneto-optic disk. The processing is executed when themode of editing is selected by a user by setting in points IN, outpoints OUT and the like by the unit of sound group in one musicalcomposition. The system control circuit 15 executes processings ofinserting, moving, exchanging or erasing in accordance with theselecting operation of the user.

As shown by FIGS. 18A and 18B, the inserting processing is a processingfor inserting a separate and new portion to one musical composition andin this case, the system control circuit 15 previously receivesdesignation of a processing point DEST showing the inserting position byoperation the jog dial 8 and records a musical play to be inserted to arecordable area of the magneto-optic disk. The system control circuit 15previously forms a part P2 in accordance with the musical play recordedin the magneto-optic disk and updates the content of the TOC memory 24such that a part P1 of one musical composition is divided into two partsP11 and P12 with the processing point DEST as a boundary. Further, thelink pointers corresponding to the parts P11 and P2 are updated suchthat the parts P11, P2 and P12 can successively be searched.

Here, the slot corresponding to the part P11 controls the start addressS1 and the end address E1 and the link pointer designates the slotcorresponding to the part P2. Further, the slot corresponding to thepart P2 controls the start address S3 and the end address E3 and thelink pointer designates the slot corresponding to the part P12.Furthermore, the slot corresponding to the part P12 controls the startaddress S2 and the end address E2 and Null is recorded to the linkpointer.

Incidentally, although according to FIG. 18B, P2 seems to beschematically inserted and the part P12 seems to be shifted, actually,they stay physically as they are shown by FIG. 18A and the U-TOCinformation is simply rewritten as described above.

Hereinafter, FIGS. 19A and 19B show schematic views in performing themoving processing.

The moving processing is a processing for moving a portion in onemusical composition is cut out and moved in the musical composition andalso in this case, the system control circuit 15 previously receivesdesignation of the processing point DEST showing an in point IN, an outpoint OUT and destination of movement by operating the jog dial 8. Thesystem control circuit 15 divides a part of one musical composition intofour parts P1, P2, P3 and P4 with the in point IN, the out point OUT andthe processing point DEST as boundaries and the respective parts areregistered in the TOC memory 24. Further, the link pointer is setbetween the respective parts such that the part between the in point INand the out point OUT can be reproduced successive to the processingpoint DEST.

As shown by FIGS. 20A and 20B, the exchanging processing is a processingfor exchanging parts in one musical composition and also in this case,the system control circuit 15 updates the content of the TOC memory 24and executes the exchanging processing similar to the case of the movingprocessing.

As shown by FIGS. 21A and 21B, the erasing processing is a processingfor erasing one portion in one musical composition and also in thiscase, the system control circuit 15 previously receives destination ofthe in point IN and the out point OUT showing an erasing start positionand an erasing finish position. The system control circuit 15 dividesthe part of one musical composition into three parts P1, P2 and P3 withthe in point IN and the out point OUT as boundaries, and the respectiveparts are registered in the TOC memory 24. Further, with respect to thepart between the in point IN and the out point OUT, the link pointer ofa corresponding socket is set such that the pointer (P-FRA) showing arecordable region can be searched and the link pointer is set betweenthe respective parts P1 and P3 such that the reproducing operation canbe carried out by omitting the part between the in point IN and the outpoint OUT. Although the part P3 is schematically described to be shiftedin FIG. 21B, actually, the part P3 stays as it is as shown by FIG. 21Aand the part P2 is only registered to P-FRA as a free area.

(1-2) Editing processing among channels

When 4 channels of audio signals are recorded in the magneto-optic disk,the editing processing among channels is an editing processing executedamong the audio signals of 4 channels at an interval by the unit ofsound group and is executed when the mode of editing is selected bysetting by a user in points IN, out points OUT and the like by the unitof sound group in one musical composition or among musical compositions.The editing processing is executed when, for example, musical plays byindividual musical instruments are allocated respectively to thechannels and parts of the respective musical plays are repeated,exchanged or added to other musical compositions.

When audio signals of 2 channels are recorded to the magneto-optic diskor when audio signals of 1 channel are recorded thereto, the editingprocessing among the channels is executed similar to the case where theaudio signals of 4 channels recorded to the magneto-optic disk areprocessed.

As shown by FIGS. 9A through 9H, when the audio signals of 4 channelsare recorded to the magneto-optic disk, according to the magneto-opticdisk device 1, the digital audio signal DA1 is formed by subjecting theaudio signals of 4 channels to time division multiplexing and therespective blocks of the digital audio signal DAI are allocated to soundgroups successively and circulatingly. By contrast, when the audiosignals of 2 channels are recorded to the magneto-optic disk as shown byFIGS. 10A through 10F, according to the magneto-optic disk 1, thedigital audio signal DA1 is formed by subjecting the audio signals of 2channels to time division multiplexing and the respective blocks of thedigital audio signals DA1 are allocated to sound groups successively andcirculatingly. Further, when the audio signals of 1 channel are recordedto the magneto-optic disk as shown by FIGS. 11A through 11D, accordingto the magneto-optic disk device 1, the digital audio signal DA1 isformed by blocking the audio signals of 1 channel by the time divisionand the respective blocks of the digital audio signal DA1 are allocatedto sound groups successively and circulatingly.

The magneto-optic disk device 1 executes the editing processing amongchannels on the basis of the case where the audio signals of 4 channelsare recorded to the magneto-optic disk. Further, when the audio signalsof 2 channels or the audio signals of 1 channel are recorded to themagneto-optic disk, similar to the case where the audio signals of 4channels are recorded to the magneto-optic disk in respect of thedigital audio signal DAI that is subjected to time axis multiplexing ortime division, by which easiness of use is promoted.

In respect of the editing processing among channels, the system controlcircuit 15 executes processings of copying, moving, exchanging orerasing in correspondence with the selecting operation of a user.

As in the above-described explanation in reference to FIGS. 9A through9H, as shown by FIG. 23A, the compressed audio signals are recorded onthe disk by the unit of cluster from the inner periphery of the disktoward the outer periphery thereof.

As shown by FIG. 23B, 1 cluster comprises 36 sectors and front 4 sectorsare used for linking areas and a sub data and the compressed main audiodata is recorded at 32 sectors thereafter.

As shown by FIG. 23C, 11 sound groups are formed at a pair of 2sectorsand 2 channel data can be recorded to 1 sound group. Now, when 4channel recording is considered, the data is recorded on the disk in theform shown by FIG. 23D.

Now, sectors allocated to the main audio data in 1 cluster comprise 32sectors and therefore, data of 32 2 11 (SG) 2=88 per cluster (block perchannel) can be recorded.

In order to facilitate the explanation hereinafter, the respectivechannel data are allocated as data rows in the longitudinal direction asshown by FIG. 23E whereby a drawing of an image as if time-sequentiallyand continuously reproduced (image of a so-called tape-like recordmedium) is shown.

Hereinafter, the drawing of FIG. 23E corresponds to FIGS. 24A, 25A, 27Aand 28A.

When a user selects the mode of copying or moving in the editingprocessing among channels, the system control circuit 15 executes aprocessing procedure shown by FIG. 22. Incidentally, the copyingprocessing is a processing for copying audio signals between an in pointIN and an out point OUT of a channel designated by the user at and afterthe processing point DEST of the channel designated by the user and themoving processing is a processing for copying audio signals between anin point IN and an out point OUT of a channel designated by the user atand after the processing point DEST of the channel designated by theuser and erasing the corresponding channel between the in point IN andthe out point OUT.

An explanation will be given of a procedure of performing the copyingprocessing or the moving processing among channels in reference to theflowchart of FIG. 22 and FIGS. 24A through 24D as follows.

A user designates an in point IN that is an editing start point and anout point OUT that is an editing finish point of a channel that is a preedit portion by using the JOG dial or the like and determines as followsa start point and a finish point of data stored to a memory with adesignated edit point as a reference.

When the in point IN that is the editing start point designated by theuser, is, for example, at 48-th cluster address, 12-th sector address,2-th sound group (hereinafter, designated by (48, 12, 2)), as areference to be stored in a memory of (48, 00, 01), that is, data from48-th cluster, 0-th sector address, 1-th sound group is reproduced andstored to the memory. This operation is performed since a unit ofwriting to the memory is the unit of cluster.

Similarly, when the out point OUT that is the editing finish pointdesignated by a user, is, for example, at 49-th cluster address, 11-thsector address, A sound group (hereinafter, designated by (49, 11, A)),as a reference for storing to the memory, data up to (49, 36, OA), thatis, 49-th cluster, 36-th sector address and A sound group is reproducedand stored to the memory.

According to the above-described example, data of 2 clusters(corresponding to n clusters in FIG. 24A) is accumulated in the memory.(refer to SP2 and SP3 of FIG. 22, and FIGS. 24A and 24B)

Next, the user designates DEST that is the processing point at the postedit portion by using the JOG dial or the like and the start point andthe finish point of the data stored to the memory is determined asfollows with the designated processing point as a reference.

The setting of the start point and the finish point depends on theamount of data determined by the in point IN that is an editing startpoint at the designated pre edit portion and the out point OUT that isthe editing finish point thereof.

Accordingly, the setting is determined such that data of 0 cluster, 31sector addresses and 8 sound groups corresponding to a differencebetween the finish point at 49-th cluster address, 11-th sector addressand A sound group and the start point at 48-th cluster address, 12-thsector address and 2 sound group, can be secured.

According to the above-described example, although it seems that data ofa maximum of 1 cluster may be stored in the memory since it is the dataamount that is less than 1 cluster, when actually, the DEST point is setin the vicinity of the end point of the cluster, a cluster disposedsuccessively must be stored.

In this way, centering on DEST, a read start cluster at a post editportion and a read finish cluster (corresponding to m cluster in FIG.24A) thereof are generated such that data amount determined by the inpoint IN that is the editing start point at the pre edit portion and theout point OUT that is the editing finish point, can sufficiently besecured, the reproducing operation is performed with the read startcluster and the read finish cluster as references and the reproduceddata is stored to the memory 20. (refer to SP4, SP5 of FIG. 22 and FIGS.24A and 24B)

In the above-described processing, attention must be paid to the pointwhere although the user designates the range as the data at the pre editportion only with respect to a specific channel, data spread on thememory includes data of other channel accompanied to the specificchannel designated by the user.

According to the recording device of the present invention, the unit ofwriting data is determined as the unit of cluster and accordingly, whendata having a length shorter than the length of a cluster is intended toedit, a total of the cluster including the short data at the pre editportion is stored once on the memory.

The operation of editing the short data after storing it to the memory,is carried out in the memory and after finishing the editing operation,the writing operation by the unit of cluster is again carried out.

The data of the channel at the copied portion designated by the user isread from the memory among the data at the pre edit portion stored tothe memory 20, and is copied to data of a channel at the copyingportion. (refer to SP6 of FIG. 22 and FIG. 24C)

After the copying processing, m cluster is read from the memory andoverwritten to a position on the disk where it is originally located.(SP7 of FIG. 22)

It is understood that by performing the above-described processing, as aresult, only the data of channel 3 is rewritten to the data of channel 1at the pre edit portion and nothing is changed with respect to otherchannel data as shown by FIG. 24D.

Although in the above-described copying processing, only the readingoperation is performed and the writing operation is not performed withrespect to the data at the pre edit portion, when the moving processingis performed, the moving processing can be realized by erasing the dataat the pre edit portion.

According to step SP8 of FIG. 22, whether a user designates the copyingprocessing or the moving processing is determined and if it is a copyingprocessing, whether all the editing operation is finished is determinedat step SP9. When the user designates the moving processing in step SP8of FIG. 22, the data at a location corresponding to the in point IN thatis the editing start point and the out point OUT that is the editingfinish point on the memory 20 (hatched portion in FIG. 24C) is allreplaced by Null data by which the portion is made soundless.

Incidentally, when the amount of data determined by the in point IN thatis the editing start point of the designated pre edit portion and theout point OUT that is the editing finish point thereof, far exceeds thecapacity of the memory 22, in the case of the copying processing, theabove-described steps of SP2, SP3, SP4, SP5, SP6, SP7, SP8 and SP9 inFIG. 22 are carried out until the copying processing is finishedsuccessively with respect to all the clusters.

Incidentally, although an explanation has been given of the editingprocessing with respect to data of 4 channels, a similar editingprocessing can be carried out also with respect to audio signals of 2channels and 1 channel by accumulating data at a pre edit portion and apost edit portion to the memory, performing actual editing operation inthe memory by the unit of sound group and rerecording the data by theunit of cluster after the editing processing.

An explanation will be given of a procedure for carrying out theexchanging processing among channels in reference to the flowchart ofFIG. 26 and schematic views of FIGS. 27A through 27D as follows.

A user designates an in point IN that is an editing start point of achannel and an out point OUT that is an editing finish point as a firstchannel data by using a JOG dial or the like and sets a start point anda finish point of data stored to a memory with a designated editingpoint as a reference.

A start point and a finish point to be read on a record medium aredetermined on the basis of the in point IN that is the designatedediting start point and the out point OUT that is the designated editingfinish point, data is reproduced and the reproduced data is stored to amemory 22.

In this case, not only the first channel data but a second through afourth channel data which are multiplexed are stored along therewith.(SP22, SP23 of FIG. 26 and FIG. 27B)

Next, the user designates DEST that is a processing point as a thirdchannel data by using a JOG dial or the like and sets the start pointand the finish point of the data stored to the memory with thedesignated processing point as a reference as follows.

According to the setting of the start point and the finish point, anarea equivalent to the amount of data determined by the in point IN thatis the editing start point of the designated first channel data and theout point OUT that is the editing finish point thereof, is secured.Incidentally, the data area secured on the memory depends on thelocation of DEST that is the processing point as described above.

The start point and the finish point to be read on the record medium onthe basis of DEST that is the processing point, are determined and thedata is reproduced and the reproduced data is stored to the memory 22.

In this case, not only the first channel data but a second through afourth channel data which are multiplexed, are stored to the memory 22along therewith. (steps SP24 and SP25 of FIG. 26 and FIG. 27B)

The desired data of a channel designated by the user is read from thememory among the first channel data stored to the memory 20 and escapedto a first register, not shown, and the third channel data is alsoescaped from the memory to a second register, not shown.

The exchanging processing is performed on the memory by using theescaped data as shown by FIG. 27C. (refer to SP26 of FIG. 26 and FIG.27C)

After performing the exchanging processing, data corresponding to thefirst channel data is read from the memory by the unit of cluster and isrerecorded at the original location and data corresponding to the thirdchannel data is read from the memory by the unit of cluster and isrerecorded at the original location. (refer to SP27 of FIG. 26 and FIG.27D)

Incidentally, although it seems that the recording operation isperformed with respect to only the hatched parts in FIG. 27D, actually,all the channel data included in the same block are overwritten. (All ofportions surrounded by bold lines in FIG. 27D)

Incidentally, when the amount of data determined by the in point IN thatis the editing start point of the set first channel data and the outpoint OUT that is the editing finish point, according to the exchangingprocessing, steps of SP22, SP23, SP24, SP25, SP26, SP27 and SP28 of FIG.26 are carried out until the exchanging processing is finishedsuccessively with respect to all the clusters.

Incidentally, although an explanation has been given of the editingprocessing with respect to data of 4 channels, the exchanging processingcan naturally be realized similarly by the unit of cluster also withrespect to audio signals of 2 channels and 1 channel.

An explanation will be given of the procedure of carrying out theerasing processing of a predetermined channel in reference to aflowchart of FIG. 28 and schematic views of FIGS. 29A through 29D asfollows.

A user designates an in point IN that is an editing start point of achannel intended to perform the erasing processing and an out point OUTthat is an editing finish point thereof by using a JOG dial or the likeand sets a reproducing start point and a reproducing finish point ofdata to be stored to a memory with a designated editing point as areference.

A reproducing start point and a reproducing finish point to be read on arecord medium is determined on the basis of the in point IN that is theset editing start point and the out point OUT that is the set editingfinish point, data is reproduced and the reproduced data is stored tothe memory 22. (steps SP32, SP33 of FIG. 28 and FIG. 29A)

In this case, not only the first channel data that is designated toerase but a second through a fourth channel data corresponding to thefirst channel data which are multiplexed, are stored along therewith.

Null data is written to the desired data of a channel designated by theuser among the first channel data stored to the memory 20. (FIG. 29C andstep SP34 of FIG. 28)

After the recording processing of Null data, data corresponding to thefirst channel data is read from the memory by the unit of cluster and isrerecorded at the original location. (refer to SP35 of FIG. 28 and FIG.29D)

Incidentally, although it seems that the recording operation is carriedout with respect to only the hatched part in FIG. 29D, actually, all thechannel data included in the same block are overwritten. (all theportion surrounded by the bold line of FIG. 27D)

Incidentally, when the amount of data determined by the in point IN thatis the editing start point of the first channel data in the set range oferasure and the out point OUT thereof, far exceeds the capacity of thememory 22, according to the exchanging processing, steps of SP32, SP33,SP34, SP35 and SP36 in FIG. 28 are carried out until the exchangingprocessing is finished successively with respect to all the clusters.

(1-3) Undo processing

According to the system control circuit 15, when the operator 7A of Undoshown by FIG. 7 is operated to push after executing the various editingprocessings, the processings of Undo and Redo are repeated incorrespondence with the pushing operation.

According to the editing processings shown by FIGS. 12A and 12B through21A and 21B, among the above-described editing processings, theoverwriting operation is not carried out and accordingly, when UTOCbefore edition that is held in the UTOC memory 24 is temporarily escapedto the escaping region provided in the UTOC memory 24 and the operator7A of Undo is operated to push, the system control circuit 15 reproducesthe state immediately before the operation and carries out theprocessings of Undo and Redo by exchanging the escaped UTOC beforeedition with UTOC after edition.

In the exchanging processing among multi channels, the processings ofUndo and Redo are carried out by repeating the processing of exchangebetween the pre edit portion and the post edit portion.

By contrast, in the copying, moving and erasing processing in theediting operation among multi channels, the audio signals recorded tothe magneto-optic disk are lost by carrying out the overwritingoperation and therefore, the system control circuit 15 previouslyescapes the audio signal before edition on the disk by the unit ofcluster and reproduces the state immediately before the operation by theescaped clusters thereby carrying out the processings of Undo and Redo.

When a user selects the copying, moving or erasing processing in theediting operation among channels, the system control circuit 15 carriesout a processing procedure shown by FIG. 30 at a predetermined period oftime and informs the user of whether the Undo processing can be carriedout previously.

According to the system control circuit 15, the operation proceeds fromstep SP41 to step SP42 and checks whether a capacity A of an escapableregion is present on the disk. As shown by FIG. 31A, the system controlcircuit 15 makes an access to the TOC memory 24, searches successivelyslots in accordance with the pointer (P-FRA) designating the recordableregion and searches the recordable region by which slots in conformitywith the amount of data to be escaped are selected.

With regard to the escapable region, the slots indicating the recordableregion designated by P-FRA are searched and the recordable capacity ofthe respective slots is spread on the UTOC memory. (SP43 of FIG. 30)

Further, according to the system control circuit 15, the operationproceeds to step SP44 and detects a capacity B of an edition settingregion by detecting the number of sound groups of data lost by editionfrom an in point IN and an out point OUT set by a user.

Successively, according to the system control circuit 15, the operationproceeds to step SP45 and whether the capacity A of the escapable regionis larger than the data amount B is determined corresponding to soundgroups of data lost by edition and when an affirmative result isobtained, the operation proceeds to step SP46 since the data lost byedition can be escaped to the escapable region by the unit of soundgroup and switches on the light emitting diodes arranged at the operator7A of Undo. Thereby, the system control circuit 15 illuminates thewindow 7B of the operator 7A in green and informs the user that the Undoprocessing can be carried out.

By contrast, when a negative result is obtained at step SP45, accordingto the system control circuit 15, the operation proceeds to step SP47and turns off the light emitting diodes arranged at the operator 7A ofUndo. Thereby, the system control circuit 15 stops illuminating thewindow 7B and informs the user that the Undo processing cannot becarried out.

When the user is informed in this way, according to the system controlcircuit 15, the operation proceeds from step SP46 or step SP47 to stepSP48 by which the processing procedure is finished. In this way, theuser can carry out the editing processing after confirming whether theUndo processing can be carried out or not and the editing processing canbe executed in the magneto-optic disk device 1 pertinently by thatamount.

Further, according to the editing operation by the unit of musicalcomposition or with respect to a portion in the musical composition (bythe unit of sound group) formed by the UTOC edition, there is no audiosignal lost by the editing operation as in the editing operation amongchannels and accordingly, the system control circuit 15 alwaysilluminates the window 7B of the operator 7A in green and informs theuser that the Undo processing can be carried out. Thereby, according tothe magneto-optic disk device 1, even when the user selects any of theediting processings, the processings of Undo and Redo can be carried outwith similar operational feeling.

That is, according to the system control circuit 15, when a useroperates the operator of execution after setting the conditions ofediting operation, a processing procedure shown by FIG. 32 is executed.Here, according to the system control circuit 15, the operation proceedsfrom step SP51 to step SP52 and whether the capacity A of the escapableregion is larger than the capacity B is determined and when anaffirmative result is obtained, the operation proceeds to step SP53.

Here, the system control circuit 15 makes an access to the TOC memory 24and rewrites the content of UTOC by which when a part of audio signalsescaped at a preceding time is present, the part is set to therecordable region. Thereby, the system control circuit 15 executesprocessing corresponding to the case where the capacity of the escapedaudio signals is added to the capacity of the recordable region by whichthe capacity A of the escapable region is set. The presence or absenceof the escaped audio signals is searched by P-TNO and whether the backupflag is set to the track mode is determined.

Successively, according to the system control circuit 15, the operationproceeds to step SP54 and as shown by FIG. 31A, data lost by the editingoperation is recorded to the recordable region by the unit of soundgroup. Here, the system control circuit 15 drives the disk unit 22 andholds the audio signal corresponding to the data amount between the inpoint IN and the out point OUT to the memory 20 by reproducing thesignal from the processing point DEST and records the demodulation dataheld by the memory 20 to the recordable region. Further, when the amountof data to be escaped is larger than the capacity of the memory 20, theprocessings of reproduction and recording are repeated by which datalost by the editing operation is escaped. Incidentally, in the erasingprocessing, the data between the in point IN and the out point OUT to beerased is escaped in place of the data at the processing point DEST andthereafter.

Further, the system control circuit 15 makes an access to the TOC memory24 and sets parts escaping the audio signals to a start address and anend address corresponding to slots designated by predetermined P-TNO. Inthis case, the system control circuit 15 sets a backup flag of the modedata (track mode) by which it is registered that the slot is a slotescaping the audio signals. By performing the above-describedprocessing, when a user simply operates the operator of reproduction,the system control circuit 15 controls the total operation such thatwith respect to the part where the backup flag is set, the reproductionis not carried out and further, the name of musical composition, thenumber of musical composition or the like is not displayed at thedisplay panel 9 whereby the escaped audio signal cannot be recognized bythe user by which the user is not confused by the escaped audio signal.

When all the data lost in this way is escaped, according to the systemcontrol circuit 15, the operation proceeds to step SP55 and carries outthe editing operation set by the user and proceeds to step SP56 by whichthe processing procedure is finished. Thereby, according to the systemcontrol circuit 15, when the operator 7A of Undo is operated by the userafter finishing the processing, the pre edit portion and the post editportion are recovered to the state immediately before the operation byusing the escaped audio signals (FIG. 25(C)).

By contrast, when a negative result is obtained at step SP52, the userrecognizes that the Undo processing cannot carried out and operates theoperator of execution by which the operation proceeds from step SP52directly to step SP55 and proceeds to step SP56 after executing theediting processing without escaping the audio signals.

Further, in the updating processing of UTOC in discharging the diskcassette 3 and in the case of the request of writing, the system controlcircuit 15 can search the part where the backup flag is set by thepointer (P-FRA) showing the recordable region and updates UTOC of themagneto-optic disk after updating the TOC memory 24 such that searchingby the pointers (P-TNO1, . . . , P-TNO255) designating the musicalcompositions is difficult.

(2) Operation of embodiments

According to the above-described constitution, when the disk cassette 3is loaded to the magneto-optic disk device 1, the control region of themagneto-optic disk is reproduced by the disk unit 22 and PTOC and UTOCof the control region is stored to the TOC memory 24.

Thereafter, when the magneto-optic disk device 1 is set to the recordmode, the audio signals SA1 through SA4 inputted from an outside device,are converted into digital audio signals at the analog to digitalconversion circuit 12 and thereafter inputted to the data compressioncircuit 13 where signals are blocked by the unit of 11.61 msec by beingsubjected to time division and the respective blocks are compressed inrespect of a time axis by data compression.

The data-compressed digital audio signals are subjected to time divisionmultiplexing successively and circulatingly by the unit of block at thesuccessive time correction circuit 14 by which 1 channel of the digitalaudio signal DA1 is formed. In this case, in recording 4 channels ofaudio signals SA1 through SA4, 4 channels of digital audio signals thetime axis of which is compressed, are switched successively andcirculatingly by the unit of block thereby forming the digital audiosignal DA1. Further, in recording 2 channels of audio signals SA1 andSA2, 2 channels of the digital audio signals the time axis of which iscompressed, are switched successively and alternately by the unit ofblock thereby forming the digital audio signal DA1. Further, inrecording 1 channel of audio signals, the digital audio signal DAl isformed from 1 channel of audio signals that is simply subjected to timedivision and data compression.

The digital audio signal DA1 formed as described above, is inputted tothe memory 20 via the bus BUS, where the signal is arranged such that 4blocks of the digital audio signal DA1 forms 2 sound groups and the datastructure of sectors are formed by adding addresses, headers or thelike. In this case, the digital audio signal DA1 is arranged toconstitute 2 sectors by 11 sound groups and when sectors for 1 clusterare formed, the digital audio signal DA1 is outputted to the signalprocessing circuit 23 as record data along with data of link sectors,sub sector, header or the like at timings in synchronism with therotation of the magneto-optic disk.

Here, the record data is added with the error correction code convertedinto modulation data by being subjected to encoding processing and amodulation magnetic field is formed by the modulation data and the audiosignals SA1 through SA4 are recorded to the magneto-optic disk bythermomagnetic recording.

According to the audio signals recorded to the magneto-optic disk inthis way, the name of musical composition, the number of musicalcomposition and the like are displayed on the display panel 9 inaccordance with the operation of a user by updating UTOC stored to theTOC memory 24.

At this occasion, according to the magneto-optic disk device, withrespect to slots corresponding to the pointers (P-TNO1, . . . ,P-TNO255), themode data (TRACKMODE) is detected by the system controlcircuit 15 and with respect to the audio signals where the backup flagis set to the mode data (TRACK MODE), the display of name of musicalcomposition, number of musical composition and the like is stopped.Thereby, the escaped audio signals where the backup flag is set, amongthe audio signals recorded to the magneto-optic disk, are held such thatthey cannot be recognized by a user by which confusion of the user caneffectively be avoided.

When the user selects musical composition and selects the reproductionmode under this state, the reproduced data is formed by the reproductionsignal obtained from the magneto-optic disk and the reproduced data isdecoded at the signal processing circuit 23. The decoded data obtainedby the decoding operation is temporarily stored in the memory 20, extradata such as header or the like is removed and the decoded data isinputted to the time correction circuit 14 by the digital audio signalDA1.

Here, the digital audio signal DA1 is converted into the digital audiosignals of the original channel number in accordance with the mode data(TRACK MODE) that is reverse to the recording operation and thereafter,subjected to data decompression at the successive data decompressioncircuit 18. Further, the digital audio signals which have been subjectedto data decompression, are converted into analog signals at the digitalto analog conversion circuit 19 and are outputted.

Also in the reproduction of the audio signals recorded on themagneto-optic disk, the audio signals where the backup flag is set, arenot reproduced and left, by which the escaped audio signals where thebackup flag is set, cannot be seen or heard by the user thereby avoidingeffectively confusion of the user.

When the user selects the mode of the editing operation tby designatingmusical compositions, the editing processing by the unit of musicalcomposition is carried out and processings of copying, moving,exchanging, erasing, combining and dividing are carried out by theso-called UTOC edition where UTOC stored to the TOC memory 24 isupdated.

Further, when the user selects the mode of the editing operation bysetting the in point IN, the out point OUT and the like by the unit ofsound group, the editing processing (editing processing by the unit ofsound group) of a portion of musical composition is carried out by thesimilar UTOC editing operation and the processing of inserting, moving,exchanging or erasing selected by the user is executed.

According to the editing processing by the unit of musical compositionand the unit of sound group, when in the TOC memory 24, UTOC at start ofedition is stored to the escaping region, the editing processing iscarried out and thereafter, the operator 7A of Undo is operated by theuser without executing successive editing processing, UTOC immediatelybefore starting the processing is reproduced by UTOC stored to theescaping region. In this way, the state immediately before starting theedition is reproduced by the reproduced UTOC and the processing of Undois carried out.

Further, in reproducing UTOC immediately before starting the processing,UTOC until that time is stored to the escaping region and when a useragain operates the operator 7A, UTOC after the editing processing isreproduced by UTOC stored to the escaping region. In this way, the stateafter the editing processing is reproduced by the reproduced UTOC andthe processing of Redo is carried out.

Meanwhile, when the user selects the mode of the editing operation bysetting the in point IN, the out point OUT and the like by the unit ofsound group in one musical composition or among musical compositions,the editing processing among channels is executed.

According to the editing processing among channels, when copyingprocessing is designated, the audio signals at the post edit portioncomprising the copied portion at and after the processing point DEST,are reproduced by a predetermined amount by the magneto-optic disk inthe unit of cluster and are stored to the memory 20 and the audiosignals at the pre edit portion comprising the audio signals between thein point IN and the out point OUT, are reproduced by a correspondingdata amount by the magneto-optic disk and are stored to the memory 20.

In this case, these audio signals are held by the memory 20 in thesector structure recorded on the magneto-optic disk, the audio signalsof a channel designated by the user are selected by the unit of soundgroup from the pre edit portion and sectors at the post edit portion areupdated by the audio signals. Thereby, in the memory 20, the audiosignals at the pre edit portion are copied to the post edit portion bythe unit of sound group among channels and the copied post edit portionis recorded at the original recording position of the magneto-opticdisk. At the pre edit portion and the post edit portion, the reproducingand recording processings are repeated by the necessary number of timesand the audio signals between the in point IN and the out point OUT arecopied to the post edit portion.

In the case of the moving operation, in addition to the updatingprocessing at the post edit portion by the copying operation, soundlessdecoded data is recorded to the channel at the pre edit portion on thememory 20. Further, in recording the post edit portion on themagneto-optic disk, the pre edit portion is also recorded on theoriginal recording position of the magneto-optic disk along therewith.In this way, according to the magneto-optic disk, in the memory 20, theaudio signals at the pre edit portion are transferred to the post editportion by the unit of sound group among channels, the pre edit portionand the post edit portion are recorded at the original recordingpositions of the magneto-optic disk and the reproducing and recordingprocessings are repeated by the necessary number of times therebytransferring the audio signals between the in point IN and the out pointOUT to the post edit portion.

In the case of the exchanging operation, in place of recording thesoundless signal in the moving processing, the audio signals at the postedit portion are recorded to the pre edit portion on the memory 20.Thereby, according to the magneto-optic disk, in the memory 20, theaudio signals at the pre edit portion and the post edit portion areexchanged by the unit of sound group among channels and thereafter, thepre edit portion and the post edit portion are recorded to the originalrecording positions of the magneto-optic disk and the reproducing andrecording processings are repeated by the necessary number of timesthereby exchanging the audio signals between the in point IN and the outpoint OUT by the audio signals at the post edit portion.

In the case of the erasing operation, only the audio signals at the preedit portion are reproduced from the magneto-optic disk and stored inthe memory 20 and the soundless signal is recorded to the channelselected by the user on the memory 20. Further, the pre edit portion isrecorded to the original region of the magneto-optic disk and thereproducing and recording processings are repeated by the necessarynumber of times. Thereby, a desired channel between the in point IN andthe out point OUT is erased by the unit of sound group.

By such an editing processing among channels, the magneto-optic diskdevice 1 can carry out, for example, an editing operation where musicalplays are recorded individually to 4 channels and parts of therespective musical plays are repeated and recorded as necessary, anediting operation where other parts are exchanged and the like by whichthe editing operation which are intended by the user, can be carried outsimply by that amount.

According to the editing processing among channels, when a user selectsprocessings of copying, moving and erasing by setting the in point INand the out point OUT, the data amount B of the audio signals lost bythe editing processing and the capacity A of the region where the audiosignals can be escaped, are detected at a constant period of time by thesystem control circuit 15. By a result of comparison between thedetected data amount B and the capacity A, whether the audio signalslost by the editing processing are escapable, is determined and whenthey are escapable, the operator 7A of Undo is illuminated in green andwhen they are difficult to escape, the illumination is turned off.

Thereby, the magneto-optic disk device 1 informs previously whether theprocessing of Undo can be performed to a user and awaits for thedetermination by the user. That is, for a user who needs Undo, when theUndo operation is difficult to execute, unnecessary musical compositionsare erased and the recordable region is enhanced and thereafter, theediting operation is continued again by which the editing processing canbe continued pertinently. Further, for a user who does not need the Undooperation, even when the Undo operation is difficult to execute, theediting operation can be continued and the editing processing can becontinued pertinently.

According to the magneto-optic disk, when a user operates the operatorof executing the editing operation in correspondence with the selectionof the user, whether the audio signals lost by the editing processingare escapable is determined and when they are escapable, the audiosignals lost by the editing processing are previously recorded to theescaping region and thereafter, the editing processing is executed.Also, when they are difficult to escape, the editing processing isdirectly executed.

In escaping the audio signals, according to the magneto-optic diskdevice 1, parts of the escaped audio signals are registered to UTOC bysetting the backup flag by which the escaped audio signals aredistinguished from other audio signals thereby effectively avoidingconfusion of the user in displaying name of musical composition, numberof musical composition and the like in the reproducing operation.

Further, in escaping the audio signals, escaped audio signals at aprevious time are erased by operating UTOC by which a reduction in therecordable region can effectively be avoided when the escapingprocessings are repeated.

Further, in discharging the disk cassette 3, parts of the escaped audiosignals are registered to UTOC as the recordable region in the casewhere writing thereof is requested, by which even when the disk cassette3 is reproduced and recorded by other magneto-optic disk device, theescaped audio signals are held such that the user cannot recognize themat all.

(3) Effect of embodiments

According to the above-described constitution, audio signals can simplybe edited among a plurality of channels by reading audio signals at apre edit portion from a magneto-optic disk by a unit of cluster andmodifying them by a unit of sound group on a memory and recording themto a post edit portion.

(4) Other embodiments

Incidentally, although in the above-described embodiments, mention hasbeen given of the case where the editing processing among channels isexecuted by processing decoded data, the present invention is notlimited thereto but is widely applicable to the case where theprocessing is performed at a stage of decompressing data and processingsof mixing or the like are executed.

Further, in such an editing operation among channels, a marker sounddesignating an in point or the like may be added on the memory 20.Incidentally, even if the marker sound is added in such a way, theoriginal audio signals are recorded and remain on the magneto-optic diskdevice by which impairment of original portions caused by adding themarker sound can effectively be avoided.

Further, although in the above-described embodiments, mention has beengiven of the case where audio signals lost by the editing operation areescaped by the unit of sound group, the present invention is not limitedthereto but the audio signals lost by the editing operation may beescaped by the unit of cluster or only the channel of the lost audiosignals may be escaped. Incidentally, in these cases, the audio signalsmay be escaped by executing the copying processing among channels orclusters may be formed only by the escaped audio signals.

Further, although in the above-described embodiments, mention has beengiven of the case where with respect to the escaped audio signals, thebackup flag is set to UTOC of sector 0 or the mode data, the presentinvention is not limited thereto but the escaped audio signals may beidentified by setting similar flags or the like.

Further, although in the above-described embodiments, mention has beengiven of the case where the audio signals lost by the editing operationare escaped to the magneto-optic disk, the present invention is notlimited thereto but the audio signals may be escaped to a magneto-opticdisk, a hard disk device, a memory or the like for operational use.Thereby, the processing of setting the backup flag can be omitted.

Further, although in the above-described embodiments, mention has beengiven of the case where the audio signals of 4 channels, 2 channels and1 channel are blocked and recorded on the magneto-optic disk, thepresent invention is not limited thereto but is applicable widely alsoin the case where the audio signals are recorded by various numbers ofchannels.

Further, although in the above-described embodiments, mention has beengiven of the case where the audio signals recorded on the magneto-opticdisk are edited, the present invention is not limited thereto but iswidely applicable to the case where audio signals recorded on variousrecord media such as an optical disk, a hard disk device, a magnetictape, a semiconductor memory and the like, are edited.

As has been described, according to the present invention, audio signalscan simply be edited among a plurality of channels by reading audiosignals at a pre edit portion from a record medium, modifying them on apredetermined storing means and rerecording them to a post edit portion.

What is claimed is:
 1. An editing device in which on a record mediumhaving a unit of writing data determined to be a predetermined length, aplurality of channel data having a unit channel data length shorter thanthe unit length of writing data are recorded after being subjected totime division multiplexing and an editing processing is performed withrespect to predetermined channels of the plurality of channels, saidediting device comprising:operating means for designating an editingrange of a specific channel data designated by a user; reproducing meansfor reproducing the plurality of channel data in respect of the editingrange from the record medium based on the editing range designated bythe operating means; storing means for storing the plurality of channeldata which have been reproduced by the reproducing means at each of theunit of writing data; erasing means for erasing the specific channeldata having the editing range designated by the user from the storingmeans; and recording means for recording again the plurality of channeldata stored to the storing means to a portion on the record mediumsituated before the editing processing after the specific channel datahas been erased on the storing means.
 2. An editing method in which on arecord medium having a unit of writing data determined to be apredetermined length, a plurality of channel data having a unit channeldata length shorter than the unit length of writing data are recorded bybeing subjected to time division multiplexing and an editing processingis performed with respect to predetermined channels of the plurality ofchannels, said editing method comprising the steps of:designating anediting range of a specific channel data designated by a user;reproducing the plurality of channel data in respect of the editingrange from the record medium based on the designated editing range;storing the reproduced plurality of channel data to a memory at each ofthe unit of writing data; erasing the specific channel data having theediting range designated by the user from the memory; and recordingagain the plurality of channel data stored to the memory to a portion onthe record medium situated before the editing processing after thespecific channel data has been erased in the memory.